District heating heat pumps

Enhance your heat production: Integrate an industrial heat pump!

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How do other district heating companies integrate heat pumps?

Local networks often have heating capacities below 1 MW. Many include a biomass boiler and a backup fossil fuel boiler. Replacing the fossil fuel boiler during plant refurbishment is both climate-conscious and economically beneficial.

Excess heat serves as an easily accessible resource when a district heating network is nearby. Various sources of waste heat, such as wastewater treatment facilities, data centers, and other industrial applications, offer potential for utilization. A heat pump converts the low-temperature available heat into high-grade thermal energy.

Integrating a large-scale heat pump into the existing plant allows the conversion of cheap electricity into heat and provides extra income from electrical grid balancing services. The most common type of heat pumps are air source. If conditions are right, geothermal or water source heat pumps may perform even better.

How does a heat pump work?

An electrically driven heat pump functions via a vapor compression cycle. At the core of this process is a substance called a refrigerant, which within this closed system experiences phase transitions. At low pressure, the refrigerant boils as it absorbs energy from the heat source. A compressor then increases the pressure by about three to seven times. The high-pressure refrigerant releases thermal energy mainly through condensation. The refrigerant then passes through an expansion device, which reduces the pressure back to a low level. By utilizing electricity as a driving force for the compressors, the cycle repeats, transferring heat from a low-temperature source to a high-temperature sink.

Heat pump sizing principles

As with any investment, achieving optimal performance is crucial, and this is particularly true for heat pumps. The dynamic nature of heat pump technology demands careful consideration. Specifically, heat pumps operate at peak efficiency when the heat source temperature is at its maximum and the heat sink temperature is at its minimum. This characteristic has significant implications for the sizing strategy.

A few points for consideration:

The balance point refers to the specific outdoor air temperature at which a heat pump is designed. As temperatures drop, the heat output of a heat pump typically decreases. While it is technically possible to design a system that relies entirely on a heat pump, achieving 100% coverage is often not economically viable, as the system would be over-engineered for the relatively few hours of extreme cold.
The operational envelope of a heat pump system must be carefully evaluated to ensure consistent performance under all conditions. During the design phase, a thorough understanding of the district heating network and the behavior of the chosen heat source is essential. This insight is crucial for selecting a suitable heat pump plant.
Heat exchanger efficiencies are critical in the design of an industrial heat pump. Each degree increase in evaporation temperature can improve efficiency by approximately 3-4%, and similarly, each degree reduction in condensation temperature impacts efficiency. Therefore, it is essential to identify and design for the optimum point tailored to the specific requirements of each individual plant.

What may go wrong?

An industrial heat pump represents a well-proven technology, with some plants installed 40 years ago still in operation.

However, risks exist with any technology. A major risk involves poor integration into the existing site. If the desired supply temperature and capacity are not achieved despite a successful Factory Acceptance Test, the problem must be identified on-site.

Another long-term issue can stem from a poor choice of refrigerant. Each unit is designed for a specific refrigerant, and switching afterward is not an option. Synthetic refrigerants negatively impact global warming and human health. Opting for a natural refrigerant that best fits the operating conditions is a wiser choice.

An oversized heat pump leads to wasted capital and may underperform at part-load conditions. Determining the optimum size before the design phase is crucial to overcoming this barrier.

Efficiency issues can stem from various sources. These may include suboptimal heat exchanger dimensioning, poor oil management, or a configuration that is not the best fit for the operating envelope.

Failing to plan is planning to fail. Any overlooked aspect specific to the technology can have a significant negative impact. The best solution to overcome any of potential risks is to invest in planning.

What do our customers say

I am very satisfied with the work you have done. You contributed exactly what I needed, which was expertise around heat pumps.
You are very technically knowledgeable about various heat pump solutions and the results you presented were very detailed and provided a good basis for further decisions.

Carl Torstensson, Driftingenjör Fjärrvärme/VA

About EKA

EKA is a specialized engineering team with a dedicated focus on heat pump and refrigeration systems. Engage EKA as your independent consultant from the initial planning phase to gain a competitive edge for your project. We design custom, manufacturer-neutral solutions for your system, ensuring the optimal choice and driving a highly competitive procurement process.